Recognize and graph periodic and trigonometric sine and cosine functions.

1. Objective Recognize and graph periodic and trigonometric sine and cosine functions.

2. Vocabulary periodic function cycle period amplitude frequency phase shift

3. Periodic functions are functions that repeat exactly in regular intervals called cycles. The length of the cycle is called its period. A cycle may begin at any point on the graph of a function.

5. Example 1A: Identifying Periodic Functions Identify whether each function is periodic. If the function is periodic, give the period. The pattern repeats exactly, so the function is periodic. Identify the period by using the start and finish of one cycle. This function is periodic with a period of .

6. Example 1B: Identifying Periodic Functions Identify whether each function is periodic. If the function is periodic, give the period. Although there is some symmetry, the pattern does not repeat exactly. This function is not periodic.

7. Example Identify whether each function is periodic. If the function is periodic, give the period. a. b.

8. The trigonometric functions that you studied in Chapter 10 are periodic. You can graph the function f(x) = sin x on the coordinate plane by using y-values from points on the unit circle where the independent variable x represents the angle θin standard position.

9. Similarly, the function f(x) = cos x can be graphed on the coordinate plane by using x-values from points on the unit circle. The amplitude of sine and cosine functions is half of the difference between the maximum and minimum values of the function. The amplitude is always positive.

11. Key Values for Functions Sine Function Cosine Function

12. You can use the parent functions to graph transformations y = a sin bx and y = a cosbx. Recall that a indicates a vertical stretch (|a|>1) or compression (0 < |a| < 1), which changes the amplitude. If ais less than 0, the graph is reflected across the x-axis. The value of b indicates a horizontal stretch or compression, which changes the period.

14. Using f(x) = sin x as a guide, graph the function g(x) = Identify the amplitude and period. Because the amplitude is Because the period is Example 2: Stretching or Compressing Functions Sine and Cosine Functions Step 1 Identify the amplitude and period.

15. The curve is vertically compressed by a factor of horizontally stretched by a factor of 2. The maximum value of g is , and the minimum value is . Example 2 Continued Step 2 Graph.

16. Using f(x) = cos x as a guide, graph the function h(x) = Identify the amplitude and period. Example Step 1 Identify the amplitude and period.

17. The maximum value of h is , and the minimum value is . Example Continued Step 2 Graph.

18. You Try Pg. 759 # 2, 3, 4, 5

19. Sine and cosine functions can be used to model real-world phenomena, such as sound waves. Different sounds create different waves. One way to distinguish sounds is to measure frequency.Frequency is the number of cycles in a given unit of time, so it is the reciprocal of the period of a function. Hertz (Hz) is the standard measure of frequency and represents one cycle per second. For example, the sound wave made by a tuning fork for middle A has a frequency of 440 Hz. This means that the wave repeats 440 times in 1 second.

20. period amplitude Example 3: Sound Application Use a sine function to graph a sound wave with a period of 0.002 s and an amplitude of 3 cm. Find the frequency in hertz for this sound wave. Use a horizontal scale where one unit represents 0.002 s to complete one full cycle. The maximum and minimum values are given by the amplitude. The frequency of the sound wave is 500 Hz.

21. period amplitude Example Use a sine function to graph a sound wave with a period of 0.004 s and an amplitude of 3 cm. Find the frequency in hertz for this sound wave. Use a horizontal scale where one unit represents 0.004 s to complete one full cycle. The maximum and minimum values are given by the amplitude. The frequency of the sound wave is 250 Hz.

22. Sine and cosine can also be translated as y = sin(x–h) + k and y = cos(x–h) + k. Recall that a vertical translation by kunits moves the graph up (k > 0) or down (k < 0). A phase shift is a horizontal translation of a periodic function. A phase shift of hunits moves the graph left (h < 0) or right (h > 0).

23. Example 4: Identifying Phase Shifts for Sine and Cosine Functions Using f(x) = sin x as a guide, graph g(x) = g(x) = sin Identify the x-intercepts and phase shift. Step 1 Identify the amplitude and period.

24. Because h = the phase shift is radians to the right. All x-intercepts, maxima, and minima of f(x) are shifted units to the right. Example 4 Continued Step 2 Identify the phase shift. Identify h.

25. The first x-intercept occurs at . Because sin x has two x-intercepts in each period of 2, the x-intercepts occur at + n, where n is an integer. Example 4 Continued Step 3 Identify the x-intercepts.

26. The maximum and minimum values occur between the x-intercepts. The maxima occur at + 2n and have a value of 1. The minima occur at + 2n and have a value of –1. Example 4 Continued Step 4 Identify the maximum and minimum values.

27. sin Example 4 Continued Step 5 Graph using all the information about the function. sin x

28. Using f(x) = cos x as a guide, graph g(x) = cos(x –). Identify the x-intercepts and phase shift. Example Step 1 Identify the amplitude and period.

29. Example Continued Step 2 Identify the phase shift.

30. Example Continued Step 3 Identify the x-intercepts.

31. Example Continued Step 4 Identify the maximum and minimum values.

32. Example Continued Step 5 Graph using all the information about the function. y cos x  x – cos (x–)

33. Amplitude Phase shift Vertical shift Period You can combine the transformations of trigonometric functions. Use the values of a, b, h, andkto identify the important features of a sine or cosine function. y =asinb(x–h)+k

34. Example

35. Example

36. You Try Pg. 759 # 7, 8, 9

37. Homework • Pgs. 759-761 #12 – 22 # 25 – 28 # 40 – 42